SE521743C2 - Stereophotographic system - Google Patents

Abstract

System provides indexes under or over pair of right and left windows of stereo slide mount which come into agreement with films' indexes when mount windows and pictures of films are brought into agreement. Frame number is written on regions outside image on film by laser beam emitters (73) located on rear of film guide (64). Printer (81) is used with detecting device (61). Base frame (51a) of stereo slide mount is mounted on mount holder (88) and print execution instruction is input. Detecting device processing unit provides data about offset position for printer control unit and printer control drives print head to print index and frame numbers. Films corresponding to film numbers printed on base frame are mounted on base frame (51a), indexes are brought into agreement with indexes of base frame and cover frame is mounted. Independent claim is included for method of mounting stereo photographs.

Description

521 743 2 a viewer a disturbing feeling when he looks at the picture, as well as a significant feeling of fatigue.

In addition, due to differences in the visual fields of the right and left shooting lenses of the stereo camera, a pair of right and left reversing films photographed by a stereo camera develop a non-overlapping portion in which the shooting areas do not match the outer edges of the images. on the right and left sides. In the non-overlapping portion, no three-dimensional image is formed even though it is viewed using a stereo image viewer. When a stereo photograph fi is viewed with two eyes without masking the non-overlapping portion, a vertical line appears, on which the edge of another window is superimposed, at a boundary between the overlapping portion and the non-overlapping portion, which disturbs interest. To prevent this, attempts have therefore been made to provide the windows of the stereo slide frame with a smaller width than the width of the film images and to place the object most severely affecting the fit between the right and left frames at nearly equal positions on the right and left frames of the stereo frame. by masking the non-overlapping portion.

The proportion of the non-overlapping portion that occupies the image increases with a decrease in the shooting distance. Therefore, fl your types of stereo slide frames are arranged, which have stepwise changed window widths, and the films are mounted by selecting the frame which has a window width which is judged to give an optimal masking amount.

However, it is not easy to determine with the eyes an appropriate amount of image masking of the elements or the amount of displacement, and stereo image frames are frequently found which give an unnatural stereo effect due to the undesirably mounted elements.

Therefore, a technical problem arises which must be solved in order to provide a stereo photographic system which makes it possible to assess the positions for mounting the films on the stereo slide picture frame, to assess an appropriate amount of image masking and to easily perform the mounting operation.

The object of the invention is to solve the above-mentioned problem.

SUMMARY OF THE INVENTION To achieve the above object, the present invention provides a stereophotographic system comprising: a stereo camera provided with the right and left shooting lenses, and an apparatus for projecting indexes on the upper or lower side of a pair of right and left angles. left images of the film at the time of shooting, and a stereo slide frame, in which indexes are arranged below or above the pair of right and left windows of the stereo slide frame to conform to said index of the images when the stereo slide frame window and the images of the images are matched with each other, so that the stereo slide picture window and the movie pictures can be easily positioned.

The invention further provides a stereophotographic system in which a suitable amount of masking or displacement of the images of the films is detected by means of a detection device, whereby perforations at the edge of the films for the image windows at this time or positions of indices recorded in advance on the edges of the films are detected. of the detected index of the film is printed on a stereo slide frame using a printer, and the films are mounted by bringing said index 'Ill-fi 521 743 into agreement with the indexes recorded on the films, so that the positions of the images of the films can be correctly determined in relative to the stereo picture frame window.

The invention further provides a stereophotographic system in which bulges are formed on a base frame of the stereo picture frame by means of a bulge generating device based on data related to the positions of the detected perforations, and the films are mounted in such a way that the film perforations engage with the bulges of the films. images can be determined correctly in relation to the stereo slide frame window.

Brief Description of the Drawings Fig. 1 is a rear view of a stereo camera, Fig. 2 is a front view of film strips photographed by the stereo camera in Figs. 1.

Fig. 3 illustrates a stereo slide picture frame of a stereo photographic system according to claim 1, in which Fig. 3a is a front view of a base frame, Figs. Fig. 3b is a side view of the base frame, Fig. 3c is a front view of a cover frame and Fig. 3d is a side view of the cover frame, Fig. 4 is a front view which, on an enlarged scale, illustrates a pin portion of the base frame, and 4b and Fig. 4c are side views of the pin portion, Figs. 5a, 5b and 5c are front views of the cover frames, Figs. Öa, 6b and 6c are front views of the cover frames, Figs. Fig. 7 is an expansion plan of a stereo slide picture frame made of a paper, Figs. 8a, 8b and 80 are front views of framing masks, Fig. 9 is a front view illustrating a position where the framing masks are mounted on the base frame, Fi. Fig. 10a is a front view of the base frame and Figs. 10b and 10c are front views of the cover frames, Fig. 11 is a rear view of a stereo camera, Fig. 12 is a front view of film strips photographed by the stereo camera of Fig. 11, Figs. 13a, 13b and 13c. is a diagram illustrating the base frames and setting gradations, Fig. 14 is a front view of the base frame, and Fig. 14b is a front view of the cover frame, Fig. 15 is a plan view illustrating the structure of a test device in a stereophotographic system, Fig. 16 is a perspective view of a printer in the stereo photographic system, Fig. 17 illustrates a focusing plate in the test device and a portion of an image sensor, wherein Figs. Fig. 17a is a front view seen from the side of the projection lenses, and Fig. 17B is a cross-sectional view thereof, Fig. 18 is a front view illustrating a portion of an imaging guide in the test device, Figs. 19a and 19b are front views of films cut into frames. Figs. 20a, 20b and 20c are front views of the base frames on which indices are printed, Fig. 21 is a front view of the base frame and Figs. Fig. 2b is a front view of the cover frame, Fig. 22 is a perspective view of a bulging device, Fig. 23 illustrates a pad plate, where Fig. 23a is a plan view, Fig. 23b is a side cross-sectional view and Fig. 23c is a bottom view, Figs. Fig. 24 is a cross-sectional view illustrating a step of forming a bulge on the base frame, and Fig. 25 is a perspective view illustrating the shape of the bulge.

Detailed Description of the Preferred Embodiments An embodiment of the present invention will now be described with reference to the drawings. A stereophotographic system according to claims 1 to 3 is composed of a stereo core having a function of exposing the films to indexes at the time of shooting, and a stereo slide picture frame provided with indexes corresponding to the index of the films.

Fig. 1 illustrates a position where a rear cover is removed from a stereo camera 1.

As with a conventional camera, a cartridge charging chamber 2 is charged at the left end of the body with a type 135 film, the end of the type 135 film is anchored to a pickup shaft 3 at the right end and the film is picked up by the pickup shaft 3. A pair of right and left shooting windows 4L and 4R are formed between the cartridge loading chamber 2 and the recording shaft 3.

A pair of right and left index exposure devices 6R and beer are arranged on an upper film guide member 5 in the film passageway. Like a general data recorder for recording dates and data related to photography, the index exposure devices 6R and 6L expose the films to light by causing LEDs to emit light while connected to shutters, S21 143; “ïfß: @ ß» ët1t 7 i purpose to register fine vertical lines on the edges at the edges that lie outside the images.

Fig. 2 illustrates film strips F photographed by the stereo camera 1. Index Mf of a vertical line is projected on the upper outside of the images 1R, 2R. lL, 2L, ---. A predetermined position ratio is maintained between the right image R and the index Mf above the right image R, and a predetermined position relationship between the left image L and the index Mf above the left image L.

The view projected on the movies through the stereo camera's lenses is turned upside down and with the higher side to the left, as seen from the back of the camera. Therefore, the films mounted on the stereo slide frame are turned 180 degrees to establish a position with a set image. In the mounted position, therefore, the index Mf is located at the lower edges of the films.

F ig. 3 illustrates a stereo slide picture frame in the stereo photographic system according to claim 1, which is composed of a base frame 11, shown in Figs. 3a and 3b and a cover frame 12 shown in Figs. 3c and 3d. The base frame 11 and the cover frame 12 are formed by injection molding a resin and provided with right windows and left windows 13R, 13L, 14R, 14L. A distance P between the windows 13R, 13L, 14R, 14L has been set to about 63 mm, which is close to the distance between the eyes of a human being. The windows 13R, l3L, l4R, l4L have vertical and lateral sizes that are almost as large as the images of the inverse glues, so that the whole pictures of the glues can be seen. Cylindrical pins 15 are erected at the top right and left and at the bottom right and left of the windows 13R, 13L of the base frame 11, and a distance between the upper and lower pins 15 is the same as the vertical width of the film F. The film is inserted between the the upper and lower positioning pins 15, and the vertical centers of the windows 13R, 13L of the base frame 11 are aligned with the vertical centers of the images F of the films. .. => .- u 521 743 8 Under the base window 1 1 window 13L there are printed indices Mm for vertical lines corresponding to the indices Mf which are registered on the elms F, in order thereby to achieve lateral positioning of the elms. When the F index Mf of the films, which are placed on the base frame 4, is matched with the index Mm of the base frame, the images of the films F are correctly matched with the windows 13R, 13L of the base frame 11.

Referring to Fig. 4, a wedge-shaped rib 15a is formed on a surface of the pin 15 in contact with the film. When the film is inserted with pressure between the pins 15 after the lateral position of the film has been determined, the rib 15 engages in the edge of the film F, so that the film F is secured.

Referring to Fig. 3c, pin holes 16 are formed in the cover frame 12 at positions which are symmetrical with the pins 15 on the base frames 11. When the pins 15 fit into the pin holes 16, the base frame 11 and the cover frame 12 join.

A vertically oriented, grooved hinge portion 12a is formed at the lateral center of the cover frame 12, and enables the cover frame 12 to fold at its center. Films are fastened in advance with fixed positions on the right and left windows of the base frame 11, the left portion of the cover frame 12 folded at the center is overlapped so that the positioning pins 15 fit into the pin holes 16 and, thereafter, the right portion of the cover frame 12 fits against the base frame 11. thereby joining the base frame 11 and the cover frame 12.

To simplify the mounting operation, an adhesive should be applied to the periphery of the right and left windows of the base frame 11. If a pressure sensitive adhesive, obtained by sealing an adhesive or a tackifier in a microcapsule, is used, adhesion will not occur undesirably until the film is positioned, and the adhesive is secured by pressing or rubbing the surface after it has been applied. location, which facilitates the assembly operation. , 1-1 in <~ ^.> F '_. . ». - f,., .... t. .-; ... In addition, a shallow cut having a vertical width equal to the vertical width of the film can be formed in the base frame, thereby positioning the film in the vertical direction, and the pins and pin heels can be used as a means of joining the base frame only and the cover frame.

The mounting system of the stereophotographic system according to claim 2 is assembled by adding several types of cover frames 12, shown in Figs. 5 and 6, to the stereo slide frame shown in Fig. 3.

The cover frame 12 includes the one (# 0) in which the gap G between the right and left windows 14R, 14L and the width W of the windows is equal to the gap GO between the windows and the width WO of the windows of the base frame 11, as shown in Fig. 3, as well as those (# 1 to # 5) in which the gap GO between the windows remains the same and the width W of the windows decreases gradually and stepwise as shown in Figs. 5a, 5b and 5G, and those (# -1 to # -3), in which the width LO between the outer edges of the right and left 14R, 14L is equal to the width LO between the outer edges of the right and left windows 13R, 13L of the base frame 11 and the width W of the window decreases stepwise, as shown in Figs. 6a, 6b and 6c. The shielding areas at the outside or inside of the images on the right and left arms change gradually depending on the identification number of the cover frame 12 associated with the base frame 11. The cover frames 12 (# -1 to # -3) are used to adjust the amount of masking at the inner ends of the films photographed in a position where the parallax is overcorrected (gap between the lenses is too small) due to improper operation using the stereo camera which is equipped with a mechanism for adjusting the distance between the optical axes. Usually, the parallax is corrected by adjusting the amount of masking at the outer ends of the images by using a stereo slide frame of # 0 to # 5. Therefore, in the stereo photographic system using a stereo camera of the type with which the distance between the optical axes is fixed, a framing system can be used without including the cover frame which is less than # -1. 521 743 åïf fl šfäï 10 A cover frame having windows with a width suitable for a certain set of stereo photographs can be selected from the above-mentioned cover frames 12 by using the mask quantity testing device already previously proposed by the applicant in the present application.

To briefly describe the test device, the right and left system devices, each of which is composed of a projection lens, have a focus plate having a collimation pattern and an eyepiece. In addition, a projection gain adjustment mechanism for providing the projection lenses in the direction of the optical axis, a mechanism for adjusting the gap between the focusing plates and an adjustment knob for merging the two adjustment mechanisms are provided.

When the imaging guide provided on the back of the projection lenses is loaded with the developed imaging strips, the images of the pair of right and left stereo photographs are projected on the imaging strips separately through the right and left projection lenses on the right and left focusing plates equipped with the same focusing plates.

The adjustment dial is provided with a dial indicating numbers corresponding to the identification numbers of the cover frames 12. In a position where 0 is set on the dial against the fixed index, the entire images of the films are projected onto the focus plates. A rotation of the adjustment knob in the positive direction or in the negative direction is accompanied by a change in the projection gain and in the gap between the focusing plates.

When the focus dial is rotated in the positive direction, the gap between the focus plates decreases at the same time as the projection gain increases, and the projection gain undergoes a change to a position where the inner and left focus plates' inner edges conform to the inner edges of the projected images. When the adjusting knob is rotated in the negative direction, the gap between the focusing plates increases at the same time as the projection gain increases, and the projection gain undergoes a change to a position where the outer and left focusing plates' outer edges conform to the projected outer edges of the projected outer edges. .

Thus, when the adjustment knob is rotated in the positive direction, the outer edges of the right and left projected images pass the outer sides of the focusing plates at the same time as the projection gain is increased, so that the outer sides of the right and left projected images are masked. When the adjustment dial is rotated in the minus direction, the inner edges of the right and left projected images go past the inner sides of the focus plates at the same time as the projection gain increases and become masked.

When the projection gain is changed by rotating the adjustment knob while observing the images on the focusing plates through the eyepiece, the perspective feeling between the collimation patterns of the focusing plates and the three-dimensional image undergoes a change. The position where the three-dimensional image is visible on the same plane as the collimation patterns or visible behind the collimation patterns is a position for an optimal image masking factor for the stereophotograph, and the number on the dial indicated by the fixed index at this time indicates the number of the cover frame of an optimal image masking factor.

Fig. 7 illustrates a stereo slide picture framing system according to a further embodiment. This slide frame 21 is obtained by punching a thick paper in a symmetrical shape in an upward-downward direction and can be folded along a horizontal line 22 at the vertical center position. The upper half cover frame 23 is folded towards this side along the fold line 22 to thereby be brought into contact with the base frame 24 of the lower half. Although not shown in diagrams, the framing system is composed of slide frames of several types (# -3 to # -5) which have stepwise changed window widths in the same way as the above-mentioned stereo slide picture framing system. d ... . -. l. The right and left windows 25R, 25L, 26R, 26L are punched in the cover frame 23 and in the base frame 24. Horizontal reference lines Lh are printed on the upper and lower sides of the windows 26R, 26L of the base frame 24 for positioning the upper and lower frames. lower edges of the inverting films. Positioning index Mm for vertical lines is printed downwards from the centers of the lower horizontal reference line Lh.

A pair of films are adhered while positioning against the right and left windows of the base frame 24, and the cover frame 23 is folded and adhered to the base frame 24 to complete the stereo slide frame. With the above-mentioned pressure-sensitive adhesive applied to the base frame 24, it is easy to staple the films together and to staple the railing frame 23 and the base frame 24 together.

A framing system in the stereophotographic system according to claim 3 is composed of the stereo slide picture frame shown in Fig. 3 and frame masks 31 (# 1 to # 5) shown in Figs. 8a, 8b and 8c, and the amount of masking of the images of the films is adjusted by the framing masks 31. .

The framing mask 31 is formed by punching windows in a light-shielding material such as paper or a black resin film. The vertical width of the framing mask 31 is greater than the width of the films and holes 31a are provided at the upper and lower portions at both the right and left ends to engage the pins 15 raised on the base frame 11 shown in Fig. 3a. the above-mentioned fog frames 12 include the framing masks 31 a plurality of types (# 1 to # 5), which have window widths which are gradually changed. The windows of the framing masks 31 have sizes which correspond to the sizes of the windows in the cover frames 12 shown in Fig. 5 of different types.

When the images are to be masked by means of the framing masks 31, the identification number of the framing masks 31 is locked by detecting the amount of masking using the detection device, and the framing masks 31 are positioned and placed on the films F so that the films F are further mounted on the base frame 1. 1, the straps F and the framing masks 31 are kept in a laminated state.

When the number of the detected mask quantity is a minus number (# -1, # -2, ---), the framing mask having a plus number whose absolute value is equal to the detected quantity can be mounted while facing right to left. For example, when the detected amount of masking is # -2, the framing mask is mounted by # 2 facing so that the right side is to the left, to mask the insides of the images of the images, and thereby to achieve the masking amount # -2.

Next, a framing system in the stereo photographic system according to claim 4 is described below. Fig. 10a illustrates a base frame 41 and Figs. 10b and 10c illustrate cover frames 42. The base frame 41 has a size equal to the size of the base frame 11 shown in Fig. 3. Under windows 43R and 43L, main scale adjustments Sm are printed on a fi setting device composed of a fl number of vertical lines. In order to make the angle of coincidence between two eyes constant independent of the amount of masking of the images, the frames 42 include a number of types (# 0 to # 5), in which the distance P between the windows 44R, 44L remains constant, but the window width W changes gradually. The pins 45 on the base frame 41 and the pin holes 46 in the cover frame 42 are arranged in the same way as those of the stereo slide picture frame according to Fig. 3.

Fig. 10 illustrates the cover frames 42 of only two types (# 3, # 5). In all cover frames, however, the distance P between the windows remains the same, and the window width decreases stepwise (W0, W1, ---) and the gap between the right and left windows increases stepwise (G0, G1, ---). When the gap G0 of the stereo slide frame 41 of # 0 forms the base, the gap between the right and left windows maintains the following conditions: (#O) GO (# 1) G1 = GO + WO - W1 (# 2) G2 = G0 + WO - W2 (# 3) G3 = G0 + WO - WS .ih, - 521 743 14 Fig. 11 illustrates a stereo camera 47 of this stereo photographic system. The upper film guide means 48 of the film passageway is provided with the index-exposing devices 49R, 49L for exposing a plurality of vertical lines forming fine-tuning gradations for light. Fig. 12 shows the film strips F photographed by the stereo camera 47 in Fig. 11. The fine tuning ratings Ss are recorded on the upper side of the images IR, 2R, 1L, 2L, ---.

The numbers of the main scale ratings Sm on the base frame 41 and the setting ratings Ss registered on the keys F correspond to the numbers of the test device number plate. When the detected mask amount is 0, as shown in Fig. 13a, the displacement of the film 0 about the main peeling gradation Sm, which is 0 on the base frame 41, is matched with 0 on the setting memory Ss of the films. Therefore, after mounting the cover frame 42 of # 0, a stereo slide frame with a mask amount of 0 has been completed.

F ig. l3b illustrates ositionlm positions when the offset amount is # 3. When the cover frame 42 of # 3 is mounted, the inner edges of the images of the panels are brought into line with the inner edges of the cover frame 42 windows, and the amount of masking becomes 0.3 mm on the outer sides of the images. Referring to Fig. 13c, when the cover frame 42 of # 2 is mounted with the offset # -2, the outer edges of the images of the frames are brought into conformity with the outer edges of the cover frame 42 window, and the amount of masking becomes 0.2 mm on the inner sides of the images.

Fig. 14 illustrates a further embodiment of a stereo slide frame utilizing the adjusting device, using a single stroke stereo slide frame having a window width smaller than the frame width WO, the positions for mounting the films on the stereo slide frame being adjusted to the left. and the outer and inner sides of the film images are partially masked to correct the parallax.

Main gradations Sm are printed on the base frame 51 in Fig. 14 in the same manner as on the base frame 41 in Fig. 10, so that the elements F on which the setting ratings Ss are projected, as shown in Fig. 12, can be positioned.

The window width of the base frame 51 and the cover frame 52 is equal, for example the window width W2 of the cover frames # 2 in Fig. 10, and is slightly narrower than the image width of the films F. However, the window width of the base frame 51 may be the same as the image width WO of the films in the same manner as of the base frame 41 of Fig. 10a.

In the adjustment type stereo slide frame, the detection device for detecting the positions of the films does not include the projection gain adjustment mechanism, but sets the projection gain constant and adjusts the gap between the right and left projection lenses or the gap between the focus plates. the optical axes.

When the adjusting knob of the detecting device is rotated from a position of an offset 0, the gap between the projection lenses and the gap between the focusing plates change relative to each other, whereby the outer or inner projected sides of the right and left projections are folded so as to lie outside the focusing plates. can observe a three-dimensional view similar to that when the outer or inner sides of the right and left images are masked.

The adjustment knob is rotated while observing the perspective view of the three-dimensional image of the focus plate collimation pattern, so that the three-dimensional image can be seen in the same plane as the collimation patterns or behind the collimation patterns. At this time, the number indicated on the dial by the fixed index shows the number of the fine-tuning gradation at which the parallax is best corrected for the stereo photograph, in the same way as for the detection device described above.

Next, a stereophotographic sister according to claim 6 is described below. This stereophotographic system is formed by a stereo camera 1, shown in Fig. 1, a stereo image frame (not shown) of a single kind, which has the same shape as 1 f - »n 521 743 ï §Ï, w3 @@: j: * 16 the stereo slide frame according to Fig. 14 but on which neither the main scale gradation nor the index is printed, a detection device and a printer for printing on the stereo slide frame a positioning index corresponding to the zero displacement position detected by detection the device.

Fig. 15 illustrates a detection device 61, which is based on a device already proposed by the applicant in the present application, and which outputs data related to the displacement amount of the projected images.

The focusing plates 63R, 63L and an imaging guide 64 are secured to the frame 62 of the detecting device 61, a screw bearing (not shown) is provided in each of the brackets 66R, 66L of the right and left separate projection lens holders 65R, 65L, and a feed screw 67, for feeding in the right-and-left direction and arranged for the frame 62 and the screw bearings of the right and left projection lens holders 65R, 651., are connected by a ball screw mechanism.

The feed screw 67 is threaded to form a right screw and a left screw symmetrically in the right-and-left direction from a center portion. When an adjusting knob 68 at the end of the feed screw 67 is rotated clockwise, the right and left projection holders 65R, 65L are separated from each other in a direction at right angles to the optical axis. When the adjustment knob 68 is turned counterclockwise, the right and left projection lens holders 65R and 65L approach each other in the direction of right angles to the optical axis.

A rotational position detector 69, such as a potentiometer or a resolver, is connected to the end of the feed screw 67, and data related to the rotational position of the screw 67 is input to the control unit (not shown).

When the projection gain is r and the width of the films is W, the width of the focus plates 63R, 63L is given as rx W. Numbers (-3 to 5) corresponding to the framing numbers (# 43 to # 5) of the stereo slide picture framing system are engraved on the dial 70 concentrically with the adjustment dial 68. When 521 743 17 When the projection gain is r and the width of the films is W, the width of the focus plates 63R, 63L is given as rx W. Numbers (-3 to 5) corresponding to the framing numbers (# -3 to # 5) of the stereo slide picture framing system are engraved on the dial 70 concentrically with the adjusting dial 68. When the number 0 of the dial 70 is brought into conformity with the fixed index 71, the main points of the projection lenses 72R, 7 2L are located on the straight lines connecting the centers of the right and left images of the film strips. which are loaded on the belt guide 64 and centers of the focusing plates 63R, 63L.

As the dial 70 is rotated in the positive direction from 0, the gap between the right and left projection lenses 72R, 72L increases, the projected images are shifted toward the outside, and the outer areas of the images are folded away toward the outside of the focusing plates 63R and 63L. Conversely, the gap between the right and left projection lenses 72R and 72L decreases when the dial 70 is rotated in the minus direction from 0, the projected images are shifted toward the inside, and the inner areas of the projected images shift toward the inner sides of the focus plates 63R, 63L, observe the view in a position where the parallax is corrected. As the displacement position detecting means, a direct-moving type of position detector such as a magnetic scale or an inductocin can be used instead of the rotational position detector 69, in order to directly detect the positions of the right and left projection lens holders 65R and 65L.

Laser beam transmitters 73 are provided on the rear surface of the film guide 64 to describe a frame number of the areas outside the images of the films. It is not easy, by using a thermal printer or an ink jet printer, to describe the frame number of the black unexposed portion of the inversion film that has been developed. However, when a laser beam is projected on the emulsion surface of the films using a laser beam transmitter, the film base heats up and destroys the arrangement of the pigment particles on this portion, so that the film base can be seen through, and even signs can be accurately detected, giving a favorable result. 521 743 18 based on the rotational position of the feeder 67 and the frame number into a memory in a control unit, and at the same time the laser beam transmitters 73 operate to register the frame numbers (nR, nL) on the lower edge of the right and left films F. The offset detection operation can be performed efficiently if a tape feeder is arranged to feed stereo images of tape strips set by set and if the laser beam transmitters 73 register the tape numbers (nR, nL) in an increasing order while connected to the measurement of the films, even if not shown in diagrams. .

Fig. 16 illustrates a printer 81 used in combination with the detection device 61. A Y-carriage 84 engages a Y-rail 83 secured to the base 82, and an X-carriage 86 engages an X-rail 85 formed on the upper surface of the Y-sled 84. On the X-carriage 86, an ink jet printhead 87 is mounted to be moved up and down in the Z direction, and a frame holder 88 secured to the base 82 is positioned below the printhead 87.

There is no particular limitation on the mechanisms for feeding the Y-carriage 84, the X-carriage 86 and the printhead 87, and any feeding mechanism can be used. For example, the feed mechanism is formed by a ball screw 89 and a servomotor 90, and a printer controller (not shown) drives the servomotor 90 to control the printhead 87 according to the three-dimensional coordinates.

A base frame 51a of a stereo slide picture frame on which no grading or index is printed is mounted on the frame holder 88, and a printer execution instruction is input. Thereafter, the printer controller reads the data related to the offset position from a data processing unit of the detecting device 61, drives the printhead 87 in the X, Y, and Z directions to print an index at positions below the base frame 5la window based on the data related to the offset position, and it prints the frame number at the center of the base frame or around the windows. 521 743 19 Films corresponding to the film numbers printed on the base frame are mounted on the base frame 51a, the indexes of the films being matched to the index of the base frame 51a, and the cover frame 52 is mounted to complete a stereo slide frame having a suitable film displacement amount.

A number of data can be stored in the detection device and in the printer. After the index marking positions of a single film or of a plurality of films have been detected, the step of printing indexes on a number of base frames can be continuously executed as it pleases.

Next, a stereo photographic system according to claim 7 is described below. This stereo photographic system uses the same stereo slide picture frame as the stereo photographic system according to claim 6. The optical system of the detection device is the same as that of the detection device 61 shown in Fig. 15.

However, instead of the rotation position detector 69 for detecting the positions of the projection lenses or focusing plates, the offset position detecting means, as shown in Fig. 17, is composed of image sensors 93R, 93L (CCD image sensors or light point detectors (PSDs) using photodiodes. left direction below the focusing plates 92R, 92L of the detection device 91 and, as shown in Fig. 18, of slots 96R, 96K opposite the focusing sensors 93R, 93L of the focusing plates 92R, 92L, the slots 96R, 96L being arranged above the windows 95R, 95L of the detection 91 'of the control means 94.

Indexes of the elements loaded on the control means 94 are exposed in the slots 96R, 96L and projected on the image sensors 93R, 93L of the focusing plates 92R, 92L. The light-receiving surfaces of the image sensors 93R, 93L are flush with the light-receiving surfaces of the focusing plates 92R, 92L to correctly detect the positions of the index Mf.

When the adjusting knob of the detecting device 91 is operated in the same manner as that of the detecting device 61 in Fig. 15, the images of the focusing plates 92R, 92L as well as the indices of the films move relative to each other in the right-and-left-hand directions in the directions. . The position ratio between the focusing plates 92R, 92L and the projected indices is the same as the position ratio between the windows and the indices of the films when the films are mounted on a single type stereo slide frame having a window smaller than the image width of the films. The offset is suitably adjusted while observing the views of the focusing plates 92R, 921, and the index positions of the films are detected by the image sensors 93R, 93L to obtain data related to the positions of the indexes to be printed on the base frame 5la of the stereo slide frame.

The data related to the index positions is supplied to the printer 81 for printing said index on the base frame 51, and the films are mounted at the same time as the index Mm of the base frame S1 is brought in accordance with the index Mf of the elements, in order to reproduce the image shift state observed by the detection device 91. using the stereo picture frame. When the lateral width of the focus plates 92R, 92L is not the same as the lateral width of the stereo picture frame window, the Y coordinates at the index print positions can be corrected depending on the size ratios.

As described above, the index positions of the films on the practice projected images are detected, and indices at the same positions as the positions of the indexes of the films are printed on the stereo picture frame. Therefore, the index positions do not necessarily have to be set constantly. Therefore, instead of projecting the said index onto the films at the time of shooting, latent index views may have been formed in advance during the film-making step, and indices appearing after the development may be used. In addition, the film control means 94 of the detection device 91 may be equipped with laser beam transmitting devices for the purpose of marking index Mf on the upper portions of the films before the detection is performed.

If the films have been perforated like the type 135 film, the perforations can be used as positioning indices in addition to using the indices registered on the films in order to detect the displacement. 521 743 ïftfiiíï? Šïšffïfïïii 21 When the perforations are to be used as a positioning index, the perforated portions of the films are exposed to the slots 96R, 96L of the film guide 94 shown in FIG. 18, and projected on the image sensors 93R, 93L which are arranged below the focusing plates 92R, 92L and are scanned in the horizontal directions by the image sensors 93R, 93L.

For example, when the perforated portions are scanned from the outer sides of the outer vertical frames of the right and left focusing plates 92R, 92L, the output of the image sensors 93R, 93L is of a white level at the time of starting the scan. Although the film F is cut at a position at a perforation P, as shown in Figs. 19A, or is cut between the perforations P, as shown in Fig. 19b, the output is therefore changed to the black level at a black portion between the perforations P.

Output data changes to the white level when the position of a first complete perforation P1 is reached after passing through the gap between the perforations, and the data related to the position is stored upon detection of this position.

Thus, the position of the outer edge of the first complete perforation P1 is detected from the starting point of the scan, and based on this position data, an index is printed on the frame by the printer 81.

When the input mechanism of the stereo camera is designed so that the distance between the images of the stereo photograph is an integer times the distance between the perforations and the gap between the images of the film strips is arranged at the positions of the perforations, the films are cut frame by frame at a position corresponding to the perforation P. where the white level changes to the black level after the start of the scan is detected by the image sensors 93R, 93L, i.e. the positions of the inner edges of the perforations PO, P7, which are cut at both ends of the films, can be detected, for use as data for index printing.

Hi i ... @> <. v 521 743 “mouse 2f1r = i; r- f:: w 1,: - 22 Fig. 20 illustrates an example of printing an index corresponding to the perforations of the elements. The shape of said index Mm may be a vertical line at the edge of the perforations, as shown in Fig. 20a. Alternatively, a stencil of a square mark having the same shape as the perforation may be stored in a drawing memory of the printer 81, and index Mm having the shape of a perforation may be written, as shown in Fig. 20b. Otherwise, the entire width of the films can be scanned by the image sensors 93R, 93L to detect the positions of perforations at both the right and left ends of the films, and an index Mm corresponding to the perforations at both the right and left ends of the films can be printed. .

In the currently used films, markings, such as frame numbers, have been projected on the upper and lower edge portions of the films. Therefore, the sensor for one-dimensional lines can often not be able to distinguish the frame numbers over the perforations. When the two-dimensional image patterns scanned by the sensor for the two-dimensional area along the perforations are analyzed by the pattern recognition unit to distinguish the perforation pattern from other patterns, such as markings, the above-mentioned mixing does not occur.

A stereo photographic system according to claim 8 is described below.

In this stereophotographic system, a stereo slide frame of a thermoplastic resin having a single window width is used and has bulges formed on the base frame of the stereo frame for positioning the films in the right and left directions.

Referring to Fig. 21, the stereo slide frame has the same shape as that shown in Fig. 14, but the base frame 101 has neither a gradation nor an index.

The bulges are formed by a bulge forming device to be described later at four corners of the windows 102R, 102L of the base frame 101 for engaging the perforations of the films. Therefore, recesses 105R, 105L are formed on the rear surface (the one which comes into contact with the base frame) at four. 23 corners of the windows 104R, 104L of the cover frame 103 to avoid interference with the bulges.

Fig. 22 illustrates a bulge forming device in which a Y-rail 114 is secured to a gate-shaped frame 13 arranged on a base 11, an electromagnetic induction heater 115 is arranged on the front left side of the gate-shaped frame 113 and a framing feed device 116. is arranged on the front right side of the gate-shaped frame 113.

A punch carriage 117 is mounted on the Y-rail 14, a Z-axis actuator 118 is attached to the front portion of the punch carriage 117, the carriage being driven by a linear servomotor (not shown), and a punch holder 119 being attached to the lower end of a hejare l18a of the Z-axis actuator 1 18.

Four round rod-type heat punches 120 are attached to the lower surface of the punch holder 119. A distance between the heat punches 120 in the X-axis direction (up-and-down direction in the drawing) is equal to the distance between the upper and lower perforations of type film. 135, and the distance between them in the Y-axis direction (right-and-left direction in the drawing) is slightly greater than the distance between the perforations at both the right and left ends of the ñlm cut into a frame.

A cushion plate raising unit 121 is attached to the right end of the gate-shaped frame 13, and a cushion plate 122 is attached to the cushion plate raising unit 121. In the die plate 122, holes 123 are provided at four locations corresponding to the four heat punches 120 of the punch holder 119. Referring to Fig. 23, circular recessed portions 123a are formed in the lower surface of the plate 122, which portions are offset from the holes 123 towards the lateral center of the pad 122. The gap between the outer peripheral surfaces of the right and left recessed portions 123a is equal to the gap between the perforations at both the right and left ends of the fi ch incised in the frame. To prevent a change in size caused by a change in temperature, it is desirable that the punch holder 119 and the pad plate 122 be made of a material having a small coefficient of expansion, and that the heat punch 120 be mounted on the punch holder 119 via a heat insulating support member. .

The framing feed device 116 has a framing carriage 125 mounted on a Y-rail 124 on its upper surface. The framing carriage 125 is displaced by a linear servomotor (not shown), and a control unit (not shown) controls the Y coordinate of the framing carriage 125 while relying on position data from the detection device 91. A framing holder portion 125a is provided on the upper surface of the framing slide 125, and the base frame 101 of the stereo slide frame is inserted and secured on the framing bracket portion 125a.

When the punch carriage 11 17 is moved to the left end of the slidable interval for lowering the punch holder 19, the four heat punches 120 are inserted into the holes at four locations in the upper surface of the electromagnetic induction heater 115 and heated by electromagnetic induction. In addition, the punch carriage 117 is moved to the right, and the feed rate is controlled so that the four heat punches 120 of the punch holder 19 are held in a position in accordance with the holes 123 at four locations of the die plate 122. After being stopped, the punch holder 119 is lowered ends are inserted into the hole 123 of the die plate 122.

The bulge forming device III is controlled for its series of operations by the control device and creates bulges on the base frame 101 based on position data regarding perforations at both the right and left ends of the fi ls detected by the detection device 91.

The operations will now be described. First, the base frame 101 of the stereo slide picture frame is mounted on the frame holder portion 125a of the frame carriage 125, and a work execution instruction is provided. Thereafter, the perforation position data is transferred from the detecting device 91 to the bulging device 11, the punch holder 119 of the punch 11 is lowered at the left end, and the heat punch 120 is inserted into the hole of the electromagnetic induction heater 115 and heated. At the same time, the control unit drives the framing carriage 125 based on perforation position data, so that the relative positions of the holes 123 of the upper pad plate 122 and of the left window 102L of the base frame 101 correspond to the relative positions of the left image and of the perforations detected by the detection device 9 1.

Thereafter, the unit 121 for raising the pad plate 122 lowers it so that it comes into intimate contact with the left window 102L of the base frame 101. The pad plate 122 is then positioned and secured at a correct working position for the left window 102L of the base frame 101. Thereafter, the heated punches 120 are raised from the electromagnetic induction heating device 115, the punch carriage 17 is moved to the right and stopped at the same position as the plate 122. Thereafter, the punch holder 119 for inserting the heat punches 120 into the hole 123 of the die plate 122 is lowered to contact the base frame. 101.

Thus, as shown in Fig. 24, the portions of the bases 101 in contact with the heat punches 120 are melted, and the molten resin fl pours into the recessed portions 1123a of the die plate 122. When the punch holder 119 is raised, the die plate 122 takes heat from the molten resin so that this solidifies and forms crescent-shaped bulges P, as shown in Fig. 25.

Thereafter, the die plate 122 is raised, and the framing slide 125 for fl is flattened so that the four points at which the bulging axes of the right window 102R of the base frame 101 are to be formed correspond to the holes 123 of the upper die plate 122.

The pad plate 122 is then lowered and brought into forced contact with the base frame 101, and the punch holder 119 is lowered to form bulges P at four locations surrounding the right window 102R of the base frame 101 in the same manner as the left window.

Although not drawn, it is convenient if a printer, such as an ink jet printer, is provided near the framing feed device 116 to print frame numbers on the base frame 101 simultaneously with the bulge forming step.

H _., .F Hm 521 743 26 The films are mounted on the base frame 101, on which the bulges P are formed in a manner described below. This means that the strips are placed at the positions of the windows in the base frame 101, perforations are brought into engagement with the four projections P around the window of the base frame 1, and the cover frame 103 is fitted against the base frame 101, so that the films are mounted in a position on the films is relatively equal to the displacement detected by the detection device 9 1.

According to the stereophotographic system according to claims 1 to 3 as described above, indices are formed on the films and on the stereo slide picture frame. Therefore, the films can be easily and correctly mounted in position.

According to the stereophotographs, the systems according to claims 4 and 5 shall be graded on the stereo slide frame film to form a fine-tuning gradation. Therefore, a system for correcting the parallax by adjusting the displacement of the films relative to the stereo slide frame window is provided, which makes it possible to correctly adjust the displacement amount.

According to the stereophotographic systems according to claims 6 to 8, indices or bulges are formed on the stereo slide frame for correctly positioning the images of the films relative to the window of the stereo slide frame. Therefore, any stereo photography can be accomplished by the simple kind of stereo slide frame, and an ideal system can be formed without the use of multi-type stereo frame frames.

The present invention is in no way limited to the above-mentioned embodiments, but can be modified in a number of different ways without departing from the technical scope of the invention, and it should be noted that such modifications are all covered by the present invention.

Claims (5)

A stereo photographic system comprising: a stereo core (1) provided with right and left shooting lenses (4L, 4R), and a device (6L, 6R) for projecting the index (Mf) on the upper or lower end. lower side of a pair of right and left images (1R, 2R, 1L, 2L) of the films (F) at the time of shooting, and a stereo slide picture frame; characterized in that the index (Mm) is arranged below or above the pair of right and left windows (1312, 13L, 14R, 14L) of the stereo slide frame to conform to said index (Mf) of the films (F) when the stereo slide frame window (F) 13R, 13L, 14R, 14L) and the images of the films (1R, 2R, 1L, 2L) are brought into line with each other. A stereo photographic system comprising: a stereo camera equipped with right and left shooting lenses (4L, 4R), a device (6L, 6R) for projecting the index (Mf) on the upper or lower side of a pair of right and left images (1R , 2R, 13L, 2L) of the films (F) at the time of shooting, and a framing system formed by your types of stereo slide frames having windows (13R, 13L, 14R, 14L) having widths which are stepwise different; characterized in that the framing system is formed by a plurality of types of stereo slide picture frames having windows (13R, 13L, 14R, 14L) having widths which are stepwise different and having indices (Mm) at positions to conform to the index (Mf) of the films. (F) when the inner edges of the right and left windows (13R, 13L, 14R, 14L) of the stereo slide picture frame are aligned with the inner edges of the (F) images of the films (1R, 2R, 1L, 2L), and a number of types of stereo picture frames having windows of different widths and having indices (Mm) at positions to conform to the index (Mf) of the films (F) when the outer edges of the right and left windows (13R, 13L , 14R, 14L) of the stereo slide picture frame are aligned with the outer edges of the (F) pictures of the films (1R, 2R, 11L, 2L); and the amount of masking of the outer areas or the inner areas of the (F) images of the films (1R, 2R, 11L, 2L) is adjusted depending on the width (W) of the stereo slide frame window (13R, 13L, 14R, 14L). . A stereo photographic system comprising: a stereo camera (1) provided with right and left shooting lenses (4L, 4R), and a device (6L, 6R) for projecting the index (Mf) on the upper or lower side of a pair of right and left images (1R, 2R, 1L, 2L) of the films (F) at the time of shooting, a stereo slide picture frame, and a number of types of framing masks (31) having windows of gradually different widths; characterized in that the index (Mm) is arranged on the lower or upper side of the pair of right and left windows (13R, 13L, 14R, 14L) of the stereo slide frame to conform to the index (Mf) of the films (Mf) when the stereo frame window match the images of the films (1R, 2R, 1L, 2L); and the framing masks (31) are mounted on the films (F) to adjust the amount of masking of the outer areas or the inner areas of the images of the films (1R, 2R, 11L, 2L) depending on the width of the window of the framing mask (31). A stereo photographic system comprising: a stereo camera (47) equipped with right and left shooting lenses, and a device (49L, 49R) for projecting fine-tuning gradations (Ss) or main-scale gradations (Sm) on the upper or lower edge portions of a pair of right and left images (1R, 2R, 1L, 2L) of the films (F) at the time of shooting, and a framing system; characterized in that the framing system is formed by a base frame (41) which registers the main shell gradations (Sm) or the fine-tuning gradations (Ss) below or above the right and left windows (43L, 43R), and a plurality of types of cover frames (42) having windows (42). 44L, 44R) with widths which gradually decrease from a width equal to the width of the images (F) of the films (1R, 2R, 1L, 2L) and which have a distance (G) between the right and left windows (44R, 44L) which is equal to the distance (G) between the windows of the base frame (41) (43L, 43R); and the positions for mounting the films (F) are set using fine tuning ratings (Ss) formed by the ratings (Sm) of the base frame (41) and of the ratings (Ss) of the films (F), and a fog frame (42). , in which the inner edges or outer edges of its window (44R, 44L) correspond to the inner edges or outer edges of the images (1R, 2R, 1L, 2L) of the mounted films, the cover frame being selected and mounted to adjust the amount of masking of the outer or inner regions of the film biases (iR, 2R, 1L, 2L). A stereo camera (47) equipped with right and left shooting lenses, a stereo photographic system comprising: device (49R, 49L) for projecting setting scans (Ss) or main scale scores (Sm) on the upper or lower edge portions of a pair of right and left images (1R, 2R, 11L, 2L) of the films (F) at the time of shooting, and a stereo slide picture frame; characterized in that the stereo slide frame has windows having a width (W) less than the width of the (F) images of the films (1R, 2R, 1L, 2L), fine-tuning gradations (Ss) or main-scale gradations (Sm) are formed below or above the right and the left windows of the stereo slide frame base frame (51), and the amount of offset of the films (F) images in the right and left directions is adjusted relative to the stereo slide frame window using fi setting gradations formed by the base frame (51) ratings and the film (F) ratings. Stereo photography system comprising: a stereo camera (1) equipped with right and left shooting lenses (4R, 4L), a device (6R, 6L) for projecting indices on the upper or lower edge portions of the right and left pictures (1R, 2R, 1L , 2L) of the films (F) at the time of shooting, a detection device (61) capable of adjusting the sense of distance of a three-dimensional view while simultaneously recording the images (1R, 2R, 1L, 2L) of the films photographed using the stereo camera, a stereo slide picture frame having windows having a width less than the width of the (F) pictures (1R, 2R, 1L, 2L) of the films, and a printing device (81) for printing the index on the lower H n ».ha,, , .r .in 1 J! l É- = r * '1 ii ". i - 3 * (H. f i. xli vvv ä' _ ,. i,. l: - ~ '' 30 or the upper side of the right and left windows of the stereo slide frame base frame (51a), characterized in that the detection device (61) includes right and left optical systems, each of which is composed of a projection lens (72R, 72L), a focusing plate (63R, 63L) having a width which is smaller than the width of the projected image and having a collimation pattern, and an eyepiece, and further including a mechanism (70) for adjusting the gap between the right and left projection lenses (72R, 72L) or the focusing plates (63R, 63L), and a gap detection mechanism (69), the images (1R, 2R, 1L, 2L) of the pair of right and left films (F) being projected separately on the right and left focus plates (63R, 63L), the gap between the right and left projection lenses (72R) being projected separately. , 72L) or the focus plates (63R, 63L) are adjusted to change the distance feeling of the three-hour the positional view, thereby detecting the displacement of the projected views producing a suitable three-dimensional effect, the printing device (81) including a control unit which corrects and prints the printing positions of the index on the base frame (51a) based on said displacement data detected by the detecting device (61). gap detection mechanism (69), and the films (F) are mounted in such a manner that said indexes recorded on the films (F) are in accordance with the indices printed by the printing device (81) on the stereo slide frame, so that the displacement of the films (F) F) images relative to the window of the stereo slide picture frame become relatively equal to the displacement of the projected images relative to the focusing plates (63R, 63L), detected by the detection device (61). A stereo photographic system comprising: a detection device (61; 9 1) capable of adjusting the distance feeling of a three-dimensional view while simultaneously recording the films (F) being photographed using a stereo camera (1), a stereo slide frame having windows with a width narrower than the width of the film (F) images (1R, 2R, 1L, 2L), and an index printing device (81) below or above the right and left windows of the base frame of the stereo slide frame; (51a); characterized in that the detection device (61; 91) includes the right and left two optical systems, each of which is composed of a projection lens (72R, 72L), a focusing plate (63R, 63L; 92R, 92L), which has a width which is smaller than the width of the projected image and which has a collimation pattern, and an eyepiece, and which further includes a mechanism (70) for adjusting the gap between the right and left projection lenses (72R, 72L) or the focusing plates (63R, 63L; 92R, 92L), the images of the pair of right and left films (F) being projected separately on the right and left focus plates (63R, 63L; 92R, 92L), the gap between the right and left projection lenses (72R, 72L) or the focus plates (63R, 63L; 92R, 92L) is adjusted to change the sense of distance of the three-dimensional view, thereby detecting the displacement of the projected views which produces a suitable three-dimensional effect, and in which an image sensor (63R, 63L 93L, 93R) or a light point detector is arranged above or below the focusing plates (63R, 63L; 92R, 92L), and a position detector unit is arranged to detect the position of a perforation (P) at the edge of the arm (F) or to detect an index (Mi) recorded on the edge of the film (F) projected on the image sensor or the light spot detector (63R, 63L; 93L, 93R), the printing device (81) includes a control unit which prints said index (Mm) on the base frame ( Sla) based on the position data for perforations (P) or indices (Mf) detected by the position detector unit of the detection device (61; 91), and the films are mounted in such a way that the indices printed by the printing device (81) on the base frame (Sla ) is in accordance with the perforation (P) or index (Mi) of the films (F), so that the displacement of the images of the films (1R, 2R, 11L, 2L) relative to the window of the stereo slide picture frame becomes relatively equal to the displacement of the projected images. in relation to the focusing plates (63R, 63L; 92R, 92L), detected by the detection device (9 1). A stereo photographic system comprising: a detection device (61; 91) capable of adjusting the distance feeling of a three-dimensional view while simultaneously recording the images of the films photographed using a stereo camera (1), a stereo slide picture frame made of a thermoplastic resin and having windows with a width narrower than the width of the images of the films (F) (1R, 2R, 1L, 2L), and a bulge-creating device (11) for creating bulges (P) below or above the right and left windows (102R, 10L) of a base frame (101) of the stereo slide frame; characterized in that the detection device (1 1 1) includes right and left optical systems, each of which is composed of a projection lens (72R, 72L), a focusing plate (63R, 63L; 92R, 92L), which has a width which is smaller than the width of the projected image and having a collimation pattern, and an eyepiece, and further including a mechanism (70) for adjusting the gap between the right and left projection lenses or focusing plates, the images (1R, 2R, 11L, 2L) of the pair of right and left films (F) are projected separately on said right and left focus plates (63R, 63L; 92R, 92L), the gap between the right and left projection lenses (72R, 72L) or the focus plates (63R, 63L; 92R, 92L ) is adjusted to change the sense of distance of the three-dimensional view, thereby detecting the displacement of the projected views which produces a suitable three-dimensional effect, and in which an image sensor or a point of light detector (93L, 93R) is disposed above or below the focusing plates (63R, 63L; 92R, 92L), and a position detector unit is provided for detecting the position of a perforation at the edge of the lens projected on the image sensor or light point detector (93L, 93R), the bulging (1 l 1) device comprising a pad (122) and heat seals (120) and includes a control unit for heat melt forming bulges (P) on the base rail (101) using -. 521 743 33 in the pad (122) and the heating pins (120) based on the position data for perforations detected by the position detector unit of the detection device (61; 91), and the films (F) are mounted in such a way that the perforations of the films (P ) engages with the bulges (P) formed by the bulge-creating device (1111) on the base frame (101), so that the displacement of the images of the films (F) (1R, 2R, 1L, 2L) relative to the windows of the stereo slide frame becomes relatively equal to the displacement of the projected images relative to the focusing plates (63R, 63L; 92R, 92L), detected by the detection device (6 1; 9 1).